ECS celebrates Krishnan (Raj) Rajeshwar, a professor, researcher, former Interface editor, and former ECS president, by honoring him, on the occasion of his 70th birthday, with a Journal of The Electrochemical Society focus issue on semiconductor electrochemistry and photoelectrochemistry.

Topics of interest include but are not limited to fundamental studies on electrochemistry, photoelectrochemistry, and semiconductor devices.

Raj has spent a great deal of his career focusing in on the understanding and application of semiconductor electrochemistry and photoelectrochemistry himself. His research also includes work in solar energy conversion, environmental chemistry, and more. It’s evident that Raj is passionate about his life’s work.

Have you made your plans yet to join us at the upcoming AiMES 2018 meeting in Cancun from September 30–October 4?

Of course, the technical program is one of the most comprehensive in the fields of electrochemistry and solid state science, but you will also have many different options for how to enjoy your free time!

The meeting will be held at the beautiful Moon Palace Resort, a gigantic luxury resort located along Cancun’s Mayan Riviera and set amidst 55-acres of lush tropical foliage. Just minutes from the Cancun International Airport, it features a full-service spa, a 27-hole golf course designed by Jack Nicklaus, a larger-than-life pool, and numerous restaurants and dining options, all making for an unforgettable experience.

The 2018 ECS Annual Business Meeting and Luncheon* will be held on Tuesday, May 15 at the 233rd ECS Meeting in Seattle, WA from 1200 – 1400h.

Featured Speaker

We are pleased to have David Danielson with a talk titled, “Electrochemistry & the Electrification of Everything in the Era of Low Cost Renewable Energy.” Danielson is the managing director of Breakthrough Energy Ventures, a new $1B+ climate-tech investment fund backed by Bill Gates and 20 other highly successful business leaders from around the world. Learn more about David Danielson and how our sciences are at the forefront of the energy revolution.

Learn and Lunch: 2017 Successes

Join past and present ECS leadership for a look at our organization and the strides made over the last year. The 2017 year was successful in many ways and the annual business meeting will give you a glimpse in program areas such as publications, meetings and, of course, membership.

Sign up when you register for the meeting. If you are already registered, you can add it by logging in to My Account > My Events > select 233rd ECS Meeting > click Add Tracks/Sessions.

The focus issue will provide a forum for the discussion of research and developments on how the central and peripheral nervous systems can be viewed and studied in terms of electrical circuits and electrochemical sensors, reactions, and methods.

The issue is dedicated to R. Mark Wightman (University of North Carolina at Chapel Hill) and Christian Amatore (Ecole Normale Supérieure), two individuals who devoted their careers to study of these topics, training and influencing countless researchers over the years.

Data science is often hailed as the fourth paradigm of science. As the computing power available to researchers increases, data science techniques become more and more relevant to a larger group of scientists. A quick literature search for electrochemistry and data science will reveal a startling lack of analysis done on the data science side. This paper is an attempt to help introduce the topics of data science to electrochemists, as well as to analyze the power of these methods when combined with physics-based models.

At the core of the paper is the idea that one cannot be successful treating every problem as a black box and applying liberal use of data science – in other words, despite its growing popularity, it is not a panacea. The image shows the basic workflow for using data science techniques – the creation of a dataset, splitting into training-test pairs, training a model, and then evaluating the model on some task. In this case, the training data comes from many simulations of the pseudo two-dimensional lithium-ion battery model. However, in order to get the best results, one cannot simply pair the inputs and outputs and train a machine learning model on it. The inputs, or features, must be engineered to better highlight changes in your output data, and sometimes the problem needs to be totally restructured in order to be successful.

A team of researchers from MIT recently demonstrated a new electrochemical method to study thermodynamic processes in an ultra-high temperature molten oxide. In an effort to find new insights into the thermodynamic properties of refractory materials, researchers have developed a container-less electrochemical method to study thermodynamic properties of materials like aluminum oxide, which melts at temperatures above 2,000 degrees Celsius.

“We have a new technique which demonstrates that the rules of electrochemistry are followed for these refractory melts,” says senior author Antoine Allanore, an associate professor of metallurgy and member of ECS. “We have now evidence that these melts are very stable at high temperature, they have high conductivity.”

The National Science Foundation is spearheading a $2.4 million research initiative to develop new methods to create commercial fertilizer out of wastewater nutrients. Among the researchers working on this project, ECS member and chair of the Society’s Energy Technology Divison, Andrew Herring, is leading an electrochemical engineering team in electrode design, water chemistry, electrochemical operations, and developing a bench-scale electrochemical reactor design.

The goal of this project is to take the nitrogen and phosphorus that exists in wastewater and transform it into fertilizer struvite, which is made up of magnesium, ammonium, and phosphate.

“Basically, you’d have a hog barn and you’d collect the liquid effluent from the farm and run it through a reactor and you’d get a solid fertilizer out of the back and, hopefully, energy,” Herring, Colorado School of Mines professor, says in a statement. “At the end of the day, we hope to optimize this thing so it makes energy, saves water, and produces fertilizer for food production.”

This work is is a collaborative effort with ECS members Lauren Greenlee, lead princial investigator and Assistant Professor at the University of Arkansas; and Julie Renner, Assistant Professor at Case Western Reserve University.

This isn’t Herring’s first foray into water and energy research. During the PRiME 2016 meeting, Herring co-organized the Energy/Water Nexus: Power from Saline Solutions symposium.

It is with great pride that ECS honors the winners of the General Student Poster Session Awards for the PRiME 2016 meeting in Honolulu, Hawaii. In following with the meeting tradition, awards recognized the top poster presentations in electrochemical and solid state categories.

ECS established the General Student Poster Session Awards in 1993 to acknowledge the eminence of its students’ work. The winners exhibit a profound understanding of their research topic and its relation to fields of interest to ECS.

In order to be eligible for the General Student Poster Session Awards, students must submit their abstracts to the Z01 General Society Student Poster Session symposium and present their posters at the biannual meeting. First and second place winners receive a certificate in addition to a cash award.

The winners of the General Student Poster Session Awards for the PRiME 2016 Meeting are as follows:

Scientists can now directly probe hard-to-see layers of chemistry due to the development of an X-ray toolkit out of Lawrence Berkeley National Laboratory.

The research team behind the initiative believes that their development could provide insight about battery performance and corrosion. Additionally, it could give insight into a variety of chemical reactions, including biological and environmental processes.

The from LBNL:

In a first-of-its-kind experiment at Berkeley Lab’s Advanced Light Source, an X-ray source known as a synchrotron, researchers demonstrated this new, direct way to study the inner workings of an activity center in chemistry known as an “electrochemical double layer” that forms where liquids meets solids—where battery fluid (the electrolyte) meets an electrode, for example (batteries have two electrodes: an anode and a cathode).

This website uses cookies so that we can provide you with the best user experience possible. Cookie information is stored in your browser and performs functions such as recognising you when you return to our website and helping our team to understand which sections of the website you find most interesting and useful.